JPH087389B2 - Method for energy subtraction of X-ray image and laminate used in the method - Google Patents

Description

The present invention relates to a method for energy subtraction of X-ray images and a radiographic film-fluorescent intensifying screen laminate used in the method. More specifically, an X-ray photo film and a fluorescent intensifying screen are used to record an X-ray image on the X-ray photo film, and then the X-ray photo film on which the X-ray image is recorded is optically scanned. X-rays in an X-ray image recording / reproducing system in which an X-ray image is photoelectrically read by a photodetector in the form of transmitted light or reflected light, the obtained image signal is subjected to signal processing, and then reproduced as a visible image. It relates to an image energy subtraction method and a radiographic film-fluorescent intensifying screen laminate used in the method.

By irradiating the same subject with X-rays having different energy distributions, a specific structure of the subject (for example, an organ, bone, blood vessel, etc.) has a specific X-ray energy absorption characteristic, and thus a specific structure is obtained. Two X-ray images with different structures extracted are obtained, and then these two X-ray images are weighted appropriately and subtraction (subtract) is performed between the two images to extract the image of the specific structure. The so-called energy subtraction method is a digital subtraction method (also referred to as digital radiography).
Hereinafter referred to as DR. ) Is known as a form. Here, the DR is a digital camera that digitally processes the output of an X-ray fluoroscopic camera consisting of an existing II tube and TV camera.
Scanned projection radiography (Scanne) that uses the fluoroscopy (Digital Fluoroscopy) and X-ray detection system used for CT such as Xe-detector
What is called d Projection Radiography) is known.

More specifically, the following various methods are known as conventional energy subtraction methods.

(I) X-rays having different energy distributions are intermittently radiated to a subject at short time intervals, and X-rays transmitted through the subject are synchronized with this, and an X-ray fluoroscopic camera or a Xe- A method of obtaining a subtraction image from two or more X-ray images obtained as a result of detection by an X-ray detector such as a detector. Here, as a method of irradiating X-rays having different energy distributions, i) modifying the X-ray source so that X-rays having such different energy distributions can be emitted, ii) different energy distributions Arranging two or more X-ray sources that emit X-rays that are close to each other so that X-rays emitted from them do not interfere with each other,
iii) There is a method of inserting and removing a filter that changes the energy distribution of X-rays between the X-ray source and the subject.

(II) Two X-ray sources capable of simultaneously emitting X-rays having different energy distributions are arranged close to each other,
Furthermore, it has a large number of fine slits or fine holes (for example, holes having a circular or square shape are arranged in a checkered pattern), and the area ratio between the X-ray shielding portion and the void portion is 1: 1. A filter made of an X-ray shielding material such as lead having the above structure is provided on one side of the X-ray detector on the light receiving surface.
The X-ray from the X-ray source and the X-ray from the other X-ray source are inserted between the X-ray source and the subject so that they do not interfere with each other. Are simultaneously irradiated with X-rays to form X-ray images on the light-receiving surface of the X-ray detector by the X-rays having different energy distributions, and the X-ray images are detected by the X-ray detector and detected. A method of separating an X-ray image at the time of reading or after reading and obtaining a subtraction image from the separated image.

(III) While moving the subject relative to the X-ray source and the X-ray detector, the X-ray source alternately and continuously generates fan-shaped X-rays having different energy distributions for a certain period of time to transmit the subject. The fan-shaped X-rays thus detected are detected by an X-ray detector installed behind the subject, X-ray images corresponding to X-rays having different energy distributions are obtained from the obtained image signals, and then subtraction images are obtained from those X-ray images. How to get. As a method of generating X-rays having different energy distributions, the same method as (I) can be considered.

(IV) A filter having the same shape as the filter used in the method (II) is formed of a metal such as copper that absorbs low energy components of X-rays, and this filter is provided between one X-ray source and the subject. When inserted, X-rays emitted from an X-ray source generate X-rays having different energy distributions that do not interfere with each other on the light-receiving surface of the X-ray detector, and X-rays are detected by the X-rays having these different energy distributions. An X-ray image is formed on the light receiving surface of the device, these X-ray images are detected by an X-ray detector, and the detected X-ray image is separated at the time of reading or after the reading, and then a subtraction image is obtained from the separated image. How to get.

The energy subtraction method can separate and extract the images of the structures having different energy absorption characteristics of the subject, and can form the image of only the soft tissue excluding the bone part. For example, it is possible to separate and extract an image of a structure such as a bronchus existing in the mediastinum, which has been difficult to be diagnosed by overlapping with a bone in the related art, from the image of the bone. In addition, when performing time subtraction in imaging such as abdominal angiography, the artifact due to abdominal gas image becomes a problem, but the energy subtraction method can erase information about soft tissue, and it can be considered as bone without gas image. It is possible to form only a contrast image. Therefore, the energy subtraction method can obtain diagnostic information that could not be obtained by the conventional method, and is a method that is attracting attention in the medical diagnostic field in principle as a very outstanding method.

However, the above-mentioned conventional energy subtraction method has an essential defect related to DR. That is, the spatial resolution of the subtraction image obtained by DR is generally determined by the resolution of an X-ray fluoroscopic camera including an II tube and a TV camera or an X-ray detector such as an Xe-detector. The resolution of the X-ray detector used for the DR is not so high, and thus the conventional energy subtraction method has a problem that it is impossible to make a fine diagnosis for a specific structure. Further, since the imaging range in the DR is limited by the light receiving area of the X-ray detector, the conventional energy subtraction method has a problem that it is not possible to simultaneously obtain a subtraction image for a wide range of structures of an object.

Further, the above-mentioned conventional energy subtraction methods (I), (II), (III) and (IV) have the following drawbacks.

1. Special X-ray source is required [method (I) and method (II)].

2. A displacement occurs between corresponding pixels of two X-ray images [method (I), method (II), method (III) and method (IV) when using two X-ray sources].

3. Only half the resolution can be obtained as compared with the usual X-ray image forming method [method (II) and method (IV)].

4. Since each X-ray image by X-rays having different energy distributions is formed on the same plane, it is difficult to separate the X-ray images at the time of reading or after the reading [method (II) and method ( IV)].

5. X-rays with different energy distributions are intermittently applied to the copy, so the images are misaligned due to muscle movement, breathing movement, peristalsis, etc. of the subject, resulting in good subtraction images. Cannot be performed [method (I)].

6. Since the subject is scanned by the fan-shaped X-ray, it takes time to form one image, and there is a time difference between the beginning and the end of the scan, and the position in each image is caused by the subject's muscular movement, respiratory movement, peristalsis, etc. As a result, a good subtraction image cannot be obtained, which is not suitable for extracting an angiographic image [Method (III)].

Therefore, the object of the present invention does not have the drawbacks that the conventional energy subtraction method has,
An object of the present invention is to provide an energy subtraction method for an X-ray image capable of obtaining a good subtraction image.

Another object of the present invention is the energy of the present invention.
It is to provide a new X-ray detector used in the subtraction method.

By the way, an X-ray image is once recorded on an X-ray photographic film, and the X-ray photographic film on which the X-ray image is recorded is optically scanned to photoelectrically convert the X-ray image in the form of transmitted light or reflected light. An X-ray photographic recording / reproducing system for recording / reproducing an X-ray image by detecting and performing signal processing on the image signal obtained by this detection and then reproducing as a visible image has already been proposed by the present applicant. (JP-A-54-121043).

Generally, an X-ray photographic film is required to have a high sensitivity and a wide exposure area suitable for X-ray photography, and to have high contrast, high sharpness and fine graininess suitable for observation and interpretation. However, these characteristics are often inconsistent with each other, and it is difficult to produce an X-ray photo film satisfying all the characteristics, and the film was designed at the sacrifice of photographing suitability and observation and interpretation suitability. However, the use of the above X-ray image recording / reproducing system can improve the contrast, sharpness, and graininess, thereby improving the diagnostic performance of the X-ray image.
Therefore, a lot of diagnostic information can be obtained and at the same time
It is possible to give the X-ray photographic film further excellent photographing suitability.

The X-ray image energy subtraction method of the present invention utilizes the X-ray image recording system.
That is, the X-ray image energy subtraction method of the present invention is replaced by the X-ray detector used in the conventional energy subtraction method described above.
X-ray film-fluorescent intensifying screen laminate in which a sheet of X-ray film is laminated with a fluorescent intensifying screen, or with a fluorescent intensifying screen and a filter composed of a substance absorbing a low energy component of X-rays Body or an X-ray photo film-fluorescent intensifying screen-filter laminate is used as an X-ray detector, and this laminate has an X-ray transmitted through an object including a specific structure having an X-ray energy absorption characteristic different from the others. And the image information of the portion corresponding to the above-mentioned specific structure is different on the laminate.
One X-ray image is recorded, and then a subtraction image is obtained from the two X-ray images read from the two films constituting the laminated body, and there is a conventional energy subtraction method. It solves the problem that was happening.

That is, the first method for energy subtraction of X-ray images of the present invention is to dispose two X-ray photographic films arranged in a laminated state and an X-ray photographic film arranged between these two X-ray photographic films. A fluorescent intensifying screen having a phosphor layer on the side thereof and having a property of absorbing low energy components of X-rays;
An X-ray film-fluorescent intensifying screen laminate comprising a fluorescent intensifying screen disposed on one outer side of one X-ray photographic film and having a phosphor layer on the side of the X-ray photographic film. X through the subject from the side where the X-ray film of the laminate is located
Of the two X-ray film films that make up the laminated body by irradiating a ray, the X-ray film film placed farther from the subject is more sensitive to the subject than the X-ray film film placed closer to the subject. X-ray images are recorded on the two X-ray photographic films so that image information reduced by absorbing low-energy components of X-rays is recorded in specific portions having different X-ray energy absorption characteristics, and then the two images are recorded. The X-ray photo film is optically scanned, the X-ray image recorded on the film is photoelectrically read in the form of transmitted light or reflected light, converted into a digital image signal, and converted into this digital image signal. Further, the digital image signal is subtracted between the corresponding pixels of the two X-ray images to extract the image of the specific structure.

The second method for energy subtraction of X-ray images of the present invention is: a) two X-ray photo films arranged in a laminated state; b) an X-ray photo film arranged between these X-ray photo films; Two fluorescent intensifying screens having a fluorescent layer on the film side, c) One of the X-ray photographic films, which is disposed on the side opposite to the fluorescent intensifying screen and which is also the X-ray photographic film. A fluorescent intensifying screen having a fluorescent layer on the side thereof, and d) a low energy component absorbing substance for X-rays interposed between two fluorescent intensifying screens arranged between the above X-ray photographic films The X-ray film-fluorescent intensifying screen-filter laminate consisting of the following is radiated with X-rays transmitted through the subject from one end side of the laminate where the X-ray photographic film is located to form this laminate. Out of the two X-ray film that is far from the subject The low-energy component of X-ray is absorbed and reduced in the portion corresponding to the above-mentioned specific structure in the X-ray photo film placed on the table, and the image information is recorded in the portion corresponding to the above-mentioned specific structure as compared with the X-ray photo film placed near the object. As described above, an X-ray image is recorded on the two X-ray photo films, and then the two X-ray photo films are optically scanned to transmit or reflect the X-ray image recorded on the film. The image of the specific structure is obtained by photoelectrically reading in the form of light and converting into a digital image signal, and subtracting the digital image signal between corresponding pixels of the two X-ray images converted into the digital image signal. Is extracted.

In the first and second energy subtraction methods of the present invention, subtracting a digital image signal between corresponding pixels of an X-ray image means adding a weighting factor to the digital image signal of the corresponding pixel of the X-ray image. This means to obtain a new image signal by multiplying and subtracting. Also, having low X-ray energy absorption characteristics means having a property of absorbing low-energy components more than high-energy X-rays. , A substance that absorbs low-energy components more than high-energy components of X-rays.

In addition, in the energy subtraction method of the first X-ray image of the present invention, the intensifying screen arranged between the two X-ray photo films is provided on both sides (the surface facing each X-ray photo film). Two fluorescent intensifying screens usually used for simple photography, which must have a fluorescent layer, and such a intensifying screen is provided with a fluorescent layer on one side of a support. , An intensifying screen provided with a fluorescent material layer on both sides of the support,
A self-supporting intensifying screen or the like consisting only of the fluorescent layer is used. In the X-ray photographic film-fluorescent intensifying screen-filter laminate used in the second X-ray image energy subtraction method of the present invention, the fluorescent sensitization film interposed between two X-ray photographic films is used. The screen consists of two fluorescent intensifying screens, and a filter is interposed between these two fluorescent intensifying screens.

In the energy subtraction method of the present invention, the spot diameter of the light beam scanning on the X-ray photographic film at the time of reading can be made small, and the number of pixels per unit area can be increased. Since the final output of the image data after the signal processing of can be recorded directly on the photosensitive material such as silver salt, it is possible to obtain a subtraction image with significantly higher spatial resolution than the conventional DR. Specifically, it is possible to obtain a clear subtraction image having a spatial resolution lower than the discrimination resolution of human vision. At the same time, there is no technical problem in increasing the area of the X-ray film or the fluorescent intensifying screen, so that a subtraction image can be obtained at once for a large area covering a wide range of structures of the human body. . Thus, the energy of the present invention
In the subtraction method, the essential problem based on the X-ray detector in DR is solved.

According to the energy subtraction method of the present invention, X-rays emitted from an X-ray source and transmitted through an object are X-ray film-fluorescent intensifying screen laminate or X-ray film-fluorescent intensifying screen-filter laminated. Since the X-ray film constituting the body is irradiated at the same time, there is no time difference between the formation of the two X-ray images to be subtracted, and therefore the subtraction image of the specific structure of the human body which changes from moment to moment. Can also be obtained as a good one. Further, in the present invention, since a single X-ray source can be used, no positional deviation occurs between the corresponding pixels of two X-ray images. Further, in the present invention, the conventional general-purpose X-ray generator and imaging apparatus can be used as they are. Furthermore, in the present invention, since X-ray images for X-rays having different energy distributions are recorded in separate X-ray photographic films, there is no problem that the images must be separated at the time of reading or after reading. Also, obtaining the subtraction image will not reduce the resolution by half. Thus, according to the energy subtraction method of the present invention, the problems of the conventional energy subtraction method can be solved at once.

As the structure of the laminate used in the energy subtraction method for X-ray images of the present invention, the following structures are specifically adopted.

That is, in the first X-ray image energy subtraction method of the present invention, for example, the fluorescing film located between the two photographic films forming the X-ray photographic film-fluorescent intensifying screen laminate. The photo intensifying screen has a characteristic of absorbing a low energy component of X-ray. In order to provide the fluorescent intensifying screen with the X-ray low energy component absorbing property, for example, the following means i), ii) or iii) are taken.

i) A phosphor having a high absorption property of low energy component of X-ray is used as a phosphor constituting the fluorescent intensifying screen, or a low energy of X-ray is contained in the phosphor layer of the fluorescent intensifying screen. Disperse the component absorbing material.

ii) A support made of an X-ray low energy component absorbing material is used as the support of the fluorescent intensifying screen. In this case, the support made of the X-ray low energy component absorbing substance may be made of only the X-ray low energy component absorbing substance, or the X-ray low energy component absorbing substance and this substance are dispersed. It may consist of another substance contained in.

iii) A combination of i) and ii) above.

In the second method for energy subtraction of X-ray images of the present invention, an X-ray is provided between two fluorescent intensifying screens arranged between two X-ray photographic films arranged in a laminated state. The low energy component of the X-ray transmitted through the subject is absorbed by the filter made of the low energy component absorbing material of (1). Also in this case, the filter made of the X-ray low energy component absorbing substance may be made of only the X-ray low energy component absorbing substance, or the X-ray low energy component absorbing substance and this substance are dispersed. It may be composed of another substance contained in the state.

Of these energy subtraction methods for X-ray images of the present invention, in the second method, the absorption of low energy components of X-rays transmitted through the subject is absorbed by a filter provided separately from the fluorescent intensifying screen. X will be done
Since the low energy component of the line can be efficiently absorbed, and the fluorescent intensifying screen used for simple photographing can be diverted as it is, the second method is the same as the first method. It is a more preferable method than the method.

As described above, the X-ray low energy component absorbing substance means a substance that absorbs the low energy component more than the high energy component of the X-ray, and specific examples thereof include metals, and particularly Cu , W, Mo, Ni, Pb, Au, Ag, Ba, Ta, Fe, Al,
At least one of Zn, Cd, Ti, Zr, V, Nb, Cr, Co and Sn
It is preferably a seed.

In the X-ray image energy subtraction method of the present invention, subtraction is performed between the corresponding pixels of two X-ray images to be subtracted to obtain a subtraction image. This subtraction is performed as described above. This means to obtain a new image signal by multiplying the image signals of the corresponding pixels of the two X-ray images to be subtracted by multiplying by the weighting coefficient. When this subtraction is expressed by an equation, L = mP-nQ (where P and Q are digital image signals of two X-ray images to be subtracted, m and n are weighting coefficients, and L is a new image signal). In order to erase the image information other than the image information regarding the specific structure to be extracted in obtaining the subtraction image, it is preferable to match the intensity distributions of the image signals of the portions to be deleted between the two images to be subtracted. For this purpose, it is convenient to match the gradation of the part to be erased. In order to realize this, it is preferable that the weighting factors m and n are selected so that the gradations of the portions to be erased of both images match and the subtraction is performed. Depending on the shooting conditions, m = n and further m = n = 1. In addition, in the two images to be subtracted, various structures are complicatedly overlapped and recorded as an integral image. Therefore, the weighting coefficient is not necessarily a constant, and in some cases, becomes a function of the thickness of the structure, It may have linearity.

As a specific method of the above subtraction, a weighting factor is selected so that the intensity distributions of regions of a structure to be erased (for example, soft tissue such as lungs in a chest image) are matched, and an image of all pixels of two images to be subtracted There is a method of multiplying the signal by the weighting factor. According to this method, the region of only the soft tissue in the two images to be subtracted has a constant intensity, and when subtraction is performed between the two images to be subtracted, the image information regarding the soft tissue is lost and only the bones are lost. Image information is extracted as a difference. Therefore, it is preferable to practice such a simple method.

In the energy subtraction method for X-ray images of the present invention, when used as X-rays for irradiating a subject with X-rays separated into a high energy band and a low energy band by a specific filter in advance, an X-ray film- Photographic intensifying screen laminate or X-ray film-Fluorescent intensifying screen-
It is preferable because the separation of the high-energy component and the low-energy component of the X-ray in the filter laminate becomes easier.

In the X-ray image energy subtraction method of the present invention, further reducing the thickness of the fluorescent intensifying screen placed at a position closer to the subject means that the fluorescent intensifying screen placed at a position farther from the subject. It is effective to prevent the reduction of the X-ray dose reaching.

In the present invention, as means for optically scanning an X-ray film for reading an X-ray image from the X-ray film, a light beam can be two-dimensionally scanned on the X-ray film, a light beam Various types of means such as electronic scanning such as a flying spot scanner, or by fixing the X-ray film on a rotating drum and moving it in a direction parallel to the rotation axis. Here, various light beams such as those obtained by condensing light emitted from a point light source with a condensing lens and laser beams can be used. Reading can be performed by detecting reflected light or transmitted light (when the X-ray film is transparent) from the X-ray image when the X-ray photographic film is optically scanned by the light detecting means.

In the energy subtraction method for an X-ray image of the present invention, various signal processing can be performed on the X-ray image before or after the subtraction, and the signal processing used is disclosed in JP-A-56-11035 and 56-11035. -75136,
No. 56-75138, No. 56-75140, No. 56-91735, etc., frequency processing, JP-A-55-116338, No. 55-88741
And the gradation processing disclosed in the publications.

 Hereinafter, the present invention will be described in detail with reference to the drawings.

FIG. 1 is a schematic cross-sectional view showing an embodiment of an X-ray film-fluorescent intensifying screen laminate used in the first X-ray image energy subtraction method of the present invention. The X-ray photo film-fluorescent intensifying screen laminate (hereinafter referred to as film intensifying screen laminate) shown in FIG. 1 is composed of two X-ray photo films A and B arranged in a laminated state. Located between the radiographic films A and B and these X
Two sheets of fluorescent intensifying screens a and b having a phosphor layer on the side of the radiographic films A and B, and one side B of the X-ray film, on the side opposite to the fluorescent intensifying screens a and b. And a fluorescent intensifying screen c having a phosphor layer on the X-ray photographic film B side. Fluorescent intensifying screen a, b
And c are fluorescent substances obtained by dispersing the X-ray fluorescent substance in a suitable binder on the supports 2a, 2b and 2c formed of an X-ray transparent material such as polyethylene terephthalate or cellulose acetate. The body layers 1a, 1b and 1c are provided. Here, the fluorescent intensifying screens a and b are phosphors having a low energy component absorbing property of X-rays, or phosphor layers 1a and 1b are used as the X-ray phosphors of the intensifying screens. The low-energy component absorbing substance for X-rays is dispersedly contained therein, so that the low-energy component absorbing property for X-ray is provided. In addition, on the surface of the phosphor layers 1a, 1b and 1c of the fluorescent intensifying screens a, b and c (the surface opposite to the side of the supports 2a, 2b and 2c), those phosphor layers are provided. A protective film such as polyethylene terephthalate film for physical or chemical protection may be provided (the same applies to the laminated body shown in FIGS. 5 to 7 below).

In the film intensifying screen laminate shown in FIG. 1, the fluorescent intensifying screens a, b and c may be so-called self-supporting fluorescent intensifying screens having no support. In this case, two sheets of self-supporting fluorescent intensifying screens a and b are replaced with one sheet of self-supporting fluorescent intensifying screen (of course, the X-ray phosphor constituting this intensifying screen is of low X-ray energy). (Having component absorption characteristics). Further, one sheet of fluorescent intensifying screens a and b having fluorescent layers provided on both sides of the support (each of the fluorescent layers provided on both sides of the support is shown in FIG. 1). Corresponding to the phosphor layers 1a and 1b) of.

FIG. 2 is a schematic diagram for explaining a state of recording an X-ray image on an X-ray photographic film by the energy subtraction method of the first X-ray image of the present invention using the film intensifying screen laminate shown in FIG. It is a figure. A single X-ray source 4 that emits X-rays 6 is arranged in the upper part of the drawing, and the film intensifying screen laminate shown in FIG. 1 is housed in a cassette 5 behind the subject 7. It is arranged.

When the X-ray 6 is emitted from the X-ray source 4, the X-ray 6 emits X-rays.
The X-ray photographic film A and the fluorescent intensifying screen a are transmitted through a subject 7 including a specific structure having a different linear energy absorption characteristic. Here, the X-ray image of the subject 7 is recorded on the X-ray photographic film A. Next, the X-rays transmitted through the X-ray photographic film A and the fluorescent intensifying screen a reach the fluorescent intensifying screens b and c and the X-ray photographic film B, and the X-ray photographic film B is irradiated with the X-rays of the subject 7. The image is recorded. Here, since the fluorescent layers 1a and 1b of the fluorescent intensifying screens a and b absorb more of the low energy components of X-rays, the low energy components of the X-rays transmitted through these fluorescent layers are reduced. Since the high energy component is emphasized, an X-ray image of the subject 7 in which the image information related to the low energy component of the X-ray is reduced is recorded on the X-ray photographic film B. In this way, two X-ray images having different image information in the portion corresponding to the specific structure of the subject 7 are simultaneously recorded on the two X-ray photographic films A and B.

An X-ray image is read from the thus obtained two X-ray photographic films A and B by a reading system as shown in FIG. 3 to obtain a digital image signal representing the image.
First, while moving the X-ray film A in the direction of arrow Y for sub-scanning, the laser light from the laser light source 10 is emitted.
The X-ray image recorded on the film 11 is read out as reflected light 13 from the X-ray photographic film A by main scanning 11 in the X direction by the scanning mirror 12. The reflected light 13 enters the inside of the condenser plate 14 from one end surface of the condenser plate 14 formed by molding a transparent acrylic plate and reaches the photo-maru 15 while repeating total reflection in the condenser plate 14, and the amount of light is the image signal S. Is output as. The output image signal S is converted into a logarithmic value (log S) digital image signal log S by a logarithmic converter 16 including an amplifier and an A / D converter.
Is converted to. This digital image signal log S is input to the digital calculator 17 and stored therein. Next, in exactly the same manner, another recorded image of the X-ray photographic film B is read out, and its digital image signal log S is stored in the digital computing unit 17. In the digital arithmetic unit 17, the digital image signal l is calculated from the digital image signal log S between the corresponding pixels.
The image signal of the specific structure to be extracted is obtained by subtracting og S. At this time, the digital image signals log S and log S
Each is multiplied by an appropriate weighting factor, but the two weighting factors are preferably chosen so that the tones of the portions of both images to be erased match. Note that the digital image signal is treated as a logarithmic value here because the band compression of the image data is performed and unnecessary image information can be completely removed. It is possible to do the same.

In this way, the signal obtained by performing the digital subtraction processing is subjected to image processing such as spatial frequency processing, gradation processing, and averaging processing, if necessary, and then displayed on a display device such as a CRT. It is reproduced directly or recorded on a recording material such as a photosensitive film as described below.

FIG. 4 shows an example of image scanning recording for reproduction. The photosensitive film 20 is moved in the sub-scanning direction of the arrow Y, and the laser beam 21 is moved onto the photosensitive film 20 in the X direction.
Direction, main scanning is performed, and the laser beam 21 is modulated by the A / O modulator 22 by the image signal from the image signal supplier 23 to form a visible image on the photosensitive film 20. If the output of the digital calculator 17 is used as this image signal, the image of the desired specific structure subjected to the digital subtraction processing can be reproduced and recorded on the photosensitive film 20.

The X-ray image of the present invention can be obtained by using the X-ray film-fluorescent intensifying screen laminate or the X-ray film-fluorescent intensifying screen-filter laminate shown in FIGS. 5 to 7 below. When performing energy subtraction, the subtraction process is performed in the same manner as described above.

FIG. 5 is a schematic sectional view showing another embodiment of the film intensifying screen laminate used in the first X-ray image energy subtraction method of the present invention. Like the laminated body of FIG. 1, the laminated body of FIG. 5 is also a laminated body of two X-ray photo films and three fluorescent intensifying screens, but is different from the laminated body of FIG. 2a and 2b of the fluorescent intensifying screens a and b interposed between the two X-ray photo films A and B are made of a substance absorbing a low energy component of X-rays. It may be composed of a low energy component absorbing substance for X-rays that has passed through and another substance containing this substance in a dispersed state, or the low energy component for X-rays is absorbed. Support 2a
And 2b may be made of only the X-ray low energy component absorbing substance.

In the laminate shown in FIG. 5, the fluorescent intensifying screen c may be a self-supporting fluorescent intensifying screen having no support. Further, the fluorescent intensifying screens a and b are X-rays as shown in FIG.
It may be replaced by a single sheet of fluorescent intensifying screen a having fluorescent layers 1a and 1a 'provided on both sides of a support 2a made of a low energy component absorbing material for lines. The fluorescent layers 1a and 1a of the fluorescent intensifying screen a shown in FIG. 6 are provided on the fluorescent layer 1a of the fluorescent intensifying screen a and the fluorescent layer 1b of the fluorescent intensifying screen b shown in FIG. 5, respectively. Equivalent to.

FIG. 7 is a schematic sectional view showing an embodiment of the X-ray film-fluorescent intensifying screen-filter laminate used in the second X-ray image energy subtraction method of the present invention. This film-intensifying screen-filter laminate comprises two radiographic films A and B arranged in a laminated state.
Two fluorescent intensifying screens a and b, which are arranged between these two radiographic films A and B and have a fluorescent layer on the side of these radiographic films A and B, of the radiographic film On the other hand, with respect to B, the fluorescent intensifying screen c and the X-ray photographic film A, which are arranged on the side opposite to the above-mentioned fluorescent intensifying screens a and b and have a phosphor layer on the side of the X-ray photographic film B. And a filter 3 made of a low-energy component for absorbing X-rays interposed between two fluorescent intensifying screens a and b arranged between B and B. The fluorescent intensifying screens a, b and c have supports 2a, 2b and 2c, respectively. However, these fluorescent intensifying screens may be self-supporting ones having no support. Good. The filter 3 may be composed of an X-ray low energy component absorbing substance and another substance containing this substance in a dispersed state, or may be composed only of an X-ray low energy component absorbing substance. The filter 3 may be provided, and the low energy component of the X-ray transmitted through the subject is absorbed by the filter 3.

As described in detail above, the X-ray image energy subtraction method of the present invention has extremely excellent characteristics, and it greatly contributes to the field of medical diagnosis.

[Brief description of drawings]

FIG. 1 is a schematic sectional view showing an embodiment of an X-ray film-fluorescent intensifying screen laminate used in the present invention, and FIG. 2 is an X-ray film-fluorescent intensifying screen laminate according to the present invention. FIG. 3 is a schematic diagram for explaining how to record an X-ray image of a subject on the X-ray image. FIG. 4 is a schematic view for explaining the steps for performing the subtraction processing, and FIG. 4 is a schematic view for explaining the steps for reproducing and recording the image subjected to the subtraction processing on the photosensitive film by using the signal obtained by the subtraction processing. Is a schematic sectional view showing another embodiment of the X-ray film-fluorescent intensifying screen laminate used in the present invention, and FIG. 7 is the X-ray film-fluorescent intensifying screen-filter used in the present invention. Laminate It is a schematic sectional view showing the embodiments with. A, B …… X-ray film a, b, c …… Fluorescent intensifying screen, 1a, 1b, 1c …… Fluorescent material layer 2a, 2b, 2c …… Support, 3 …… Filter, 4… … X-ray source 6 …… X-ray, 7 …… Subject, 10 …… Laser light source 11 …… Laser light, 12 …… Scanning mirror, 13 …… Reflected light 14 …… Concentrator, 15 …… Photomul, 16 …… Logarithmic converter 17 …… Digital calculator, 20 …… Photosensitive film 21 …… Laser light, 22 …… A / O modulator 23 …… Image signal feeder

 ─────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-53-126922 (JP, A) JP-A-53-520842 (JP, A) Actually developed JP-A-56-146250 (JP, U)

Claims (25)

[Claims] 1. An X-ray is irradiated to an object including a plurality of structures having different X-ray energy absorption characteristics, and the X-ray transmitted through the object is a) two X-ray photographs arranged in a laminated state. A film, b) a fluorescent intensifying screen disposed between the X-ray film and having a phosphor layer on the side of the X-ray film, and c) with respect to one of the X-ray film, The fluorescent intensifying screen is arranged on the side opposite to the paper and has a phosphor layer on the side of the X-ray photographic film. The fluorescent intensifying screen arranged between the X-ray photographic films is X-ray. X-ray film-fluorescent intensifying screen laminate having a low energy component absorption characteristic of X-ray is irradiated from one end side of the laminate where the X-ray film is located, and two X's constituting the laminate are formed. An X-ray film placed farther from the subject in the X-ray film The low energy component of X-rays is more absorbed and reduced in the portion corresponding to the target specific structure than the X-ray film placed closer to the subject, and the reduced image information is recorded as described above. The X-ray image is recorded on one X-ray photographic film, and then the above 2
An X-ray photographic film is optically scanned, the X-ray image recorded on the film is photoelectrically read in the form of transmitted light or reflected light, converted into a digital image signal, and converted into this digital image signal. An energy subtraction method for an X-ray image, which comprises subtracting a digital image signal between corresponding pixels of the two generated X-ray images to extract an image of the specific structure of interest. 2. A fluorescent material having a characteristic of absorbing a low energy component of X-rays is used for the fluorescent intensifying screen located between the two X-ray photographic films.
An X-ray image energy subtraction method according to the above item. 3. The phosphor layer of the fluorescent intensifying screen located between the two X-ray photographic films is a phosphor layer in which a low energy component absorbing substance for X-rays is dispersedly contained. An X-ray image energy subtraction method according to claim 1. 4. The fluorescent intensifying screen located between the two X-ray film has a support, and the support is made of a low energy component absorbing material for X-rays. An X-ray image energy subtraction method according to claim 1. 5. The support according to claim 4, wherein the support is composed of the substance absorbing the low energy component of the X-ray and another substance containing the substance in a dispersed state. X-ray image energy subtraction method. 6. The energy subtraction method for an X-ray image according to claim 4, wherein the support comprises only the X-ray low energy component absorbing material. 7. The X-ray according to claim 1, wherein the fluorescent intensifying screen located between the two X-ray photographic films is two fluorescent intensifying screens. Image energy
Subtraction method. 8. A fluorescent intensifying screen located between the two X-ray film is one fluorescent intensifying screen having a phosphor layer on both sides thereof. An energy subtraction method for an X-ray image according to claim 1. 9. The energy subtraction method for an X-ray image according to any one of claims 3 to 6, wherein the substance absorbing the low energy component of the X-ray is a metal. 10. The metal is Cu, W, Mo, Ni, Pb, Au, Ag, Ba, Ta,
10. Energy subtraction of an X-ray image according to claim 9, wherein the energy subtraction is at least one of Fe, Al, Zn, Cd, Ti, Zr, V, Nb, Cr, Co and Sn. Method. 11. An object including a plurality of structures having different X-ray energy absorption characteristics is irradiated with X-rays, and the X-rays transmitted through the object are a) two X-ray photographs arranged in a laminated state. A film, b) two fluorescent intensifying screens arranged between these radiographic films and having a phosphor layer on the side of these radiographic films, c) with respect to one of said radiographic films, said fluorescent film A fluorescent intensifying screen disposed on the side opposite to the intensifying screen and having a phosphor layer on the side of the radiographic film, and d) two fluorescents disposed between the radiographic films. An X-ray photographic film-fluorescent intensifying screen-filter laminate comprising a filter made of a substance absorbing a low energy component of X-rays interposed between intensifying screens, and one end where the X-ray photographic film of the laminate is located. Two X-ray photographic films that are irradiated from the side to form the laminate. The low-energy component of X-rays is greater in the portion of the X-ray film placed farther from the subject than in the X-ray film placed closer to the subject than the X-ray film placed closer to the subject. An X-ray image is recorded on the two X-ray photo films so that the absorbed and reduced image information is recorded, and then the two X-ray photo films are optically scanned and recorded on the film. The present X-ray image is photoelectrically read in the form of transmitted light or reflected light, converted into a digital image signal, and the subtraction of the digital image signal between the corresponding pixels of the two X-ray images converted into this digital image signal. An energy subtraction method for an X-ray image, characterized in that the image of a specific structure of interest is extracted. 12. The filter according to claim 1, wherein the filter comprises the substance for absorbing the low energy component of the X-ray and another substance containing the substance in a dispersed state.
An X-ray image energy subtraction method according to the above item. 13. The energy subtraction method for an X-ray image according to claim 11, wherein the filter is made of only a substance for absorbing the low energy component of the X-ray. 14. The energy subtraction method for an X-ray image according to any one of claims 11 to 13, wherein the substance absorbing the low energy component of the X-ray is a metal. 15. The metal is Cu, W, Mo, Ni, Pb, Au, Ag, Ba, Ta,
15. Energy subtraction of an X-ray image according to claim 14, which is at least one of Fe, Al, Zn, Cd, Ti, Zr, V, Nb, Cr, Co and Sn. Method. 16. A fluorescent sensitization comprising: a) two radiographic films arranged in a laminated state; b) a radiographic film disposed between these radiographic films and having a phosphor layer on the side of the radiographic films. Paper, and c) one side of the X-ray photographic film, which comprises a fluorescent intensifying screen which is disposed on the side opposite to the fluorescent intensifying screen and which has a phosphor layer on the side of the X-ray photographic film. An X-ray film-fluorescent intensifying screen laminate characterized in that the fluorescent intensifying screen arranged between the X-ray photographic films has low X-ray energy absorption characteristics. A subject including a plurality of structures having different linear energy absorption characteristics is irradiated with X-rays, and X-rays transmitted through the subject are irradiated from one end side where the X-ray photographic film of the laminate is located to form the laminate. Place it in a position far from the subject of the two X-ray film On the burned X-ray film,
The above two sheets so that the low energy component of X-rays is more absorbed and reduced in the portion corresponding to the target specific structure than the X-ray photo film placed closer to the subject and the reduced image information is recorded. X-ray image is recorded on the X-ray photographic film, and then the two X-ray photographic films are optically scanned to photoelectrically convert the X-ray image recorded on the film into transmitted light or reflected light. And read it to convert it into a digital image signal, and subtract the digital image signal between the corresponding pixels of the two X-ray images converted into this digital image signal to extract the image of the target specific structure. An X-ray film-fluorescent intensifying screen laminate used in an energy subtraction method for X-ray images. 17. A fluorescent intensifying screen located between the two X-ray photographic films is provided with a fluorescent material having a property of absorbing low energy components of X-rays. An X-ray film-fluorescent intensifying screen laminate according to item 16. 18. A patent characterized in that a fluorescent substance layer of a fluorescent intensifying screen located between the two X-ray photographic films contains a low energy component absorbing substance for X-rays dispersedly contained therein. An X-ray film-fluorescent intensifying screen laminate according to claim 16. 19. The fluorescent intensifying screen located between the two X-ray film has a support, and the support is made of a low energy component absorbing material for X-rays. A radiographic film according to claim 16, characterized in that
Fluorescent intensifying screen laminate. 20. The method according to claim 19, wherein the support is composed of the X-ray low energy component absorbing substance and another substance containing the substance in a dispersed state. X-ray film-fluorescent intensifying screen laminate. 21. The X-ray photographic film-fluorescent intensifying screen laminate according to claim 19, wherein the support comprises only the X-ray low energy component absorbing material. 22. The X-ray according to claim 16, wherein the fluorescent intensifying screen located between the two X-ray photographic films is two fluorescent intensifying screens. Photo film-fluorescent intensifying screen laminate. 23. The fluorescent intensifying screen located between the two X-ray film is one fluorescent intensifying screen having a phosphor layer on both sides thereof. An X-ray film-fluorescent intensifying screen laminate according to item 16. 24. The X-ray photographic film-fluorescent intensifying screen according to any one of claims 18 to 21, wherein the substance absorbing the low energy component of X-rays is a metal. Laminate. 25. The metal is Cu, W, Mo, Ni, Pb, Au, Ag, Ba, Ta,
25. An X-ray film-fluorescent film according to claim 24, which is at least one of Fe, Al, Zn, Cd, Ti, Zr, V, Nb, Cr, Co and Sn. Intensifying screen laminate.